def curry2(func):
    def excute_func(x):
        def inner(y):
            return func(x, y)
        return inner
    return excute_func

def lambda_curry2(func):
    """
    Returns a Curried version of a two-argument function FUNC.
    >>> from operator import add, mul, mod
    >>> curried_add = lambda_curry2(add)
    >>> add_three = curried_add(3)
    >>> add_three(5)
    8
    >>> curried_mul = lambda_curry2(mul)
    >>> mul_5 = curried_mul(5)
    >>> mul_5(42)
    210
    >>> lambda_curry2(mod)(123)(10)
    3
    >>> # You aren't expected to understand the code of this test.
    >>> # This checks to make sure that you only use one line.
    >>> import inspect, ast
    >>> [type(x).__name__ for x in ast.parse(inspect.getsource(lambda_curry2)).body[0].body]
    ['Expr', 'Return']
    """
    return lambda x: lambda y: func(x, y)


def sum_digits(y):
    """Return the sum of the digits of non-negative integer y."""
    total = 0
    while y > 0:
        total, y = total + y % 10, y // 10
    return total

def is_prime(n):
    """Return whether positive integer n is prime."""
    if n == 1:
        return False
    k = 2
    while k < n:
        if n % k == 0:
            return False
        k += 1
    return True

def count_cond(condition):
    """Returns a function with one parameter N that counts all the numbers from
    1 to N that satisfy the two-argument predicate function Condition, where
    the first argument for Condition is N and the second argument is the
    number from 1 to N.

    >>> count_fives = count_cond(lambda n, i: sum_digits(n * i) == 5)
    >>> count_fives(10)   # 50 (10 * 5)
    1
    >>> count_fives(50)   # 50 (50 * 1), 500 (50 * 10), 1400 (50 * 28), 2300 (50 * 46)
    4

    >>> is_i_prime = lambda n, i: is_prime(i) # need to pass 2-argument function into count_cond
    >>> count_primes = count_cond(is_i_prime)
    >>> count_primes(2)    # 2
    1
    >>> count_primes(3)    # 2, 3
    2
    >>> count_primes(4)    # 2, 3
    2
    >>> count_primes(5)    # 2, 3, 5
    3
    >>> count_primes(20)   # 2, 3, 5, 7, 11, 13, 17, 19
    8
    """
    "*** YOUR CODE HERE ***"
    def cond(n):
        i = 1
        count = 0
        while i <= n:
            if condition(n, i):
                count += 1
            i += 1
        return count
    return cond



def cycle(f1, f2, f3):
    """Returns a function that is itself a higher-order function.

    >>> def add1(x):
    ...     return x + 1
    >>> def times2(x):
    ...     return x * 2
    >>> def add3(x):
    ...     return x + 3
    >>> my_cycle = cycle(add1, times2, add3)
    >>> identity = my_cycle(0)
    >>> identity(5)
    5
    >>> add_one_then_double = my_cycle(2)
    >>> add_one_then_double(1)
    4
    >>> do_all_functions = my_cycle(3)
    >>> do_all_functions(2)
    9
    >>> do_more_than_a_cycle = my_cycle(4)
    >>> do_more_than_a_cycle(2)
    10
    >>> do_two_cycles = my_cycle(6)
    >>> do_two_cycles(1)
    19
    """
    "*** YOUR CODE HERE ***"
    def g(n):
        def h(x):
            i = 0
            result = 0
            while(i <= n):
                if (i == 0):
                    result = x
                elif i % 3 == 1:
                    result = f1(result)
                elif i % 3 == 2:
                    result = f2(result)
                elif i % 3 == 0:
                    result = f3(result)
                i += 1
            return result
        return h
    return g


def composite_identity(f, g):
    """
    Return a function with one parameter x that returns True if f(g(x)) is
    equal to g(f(x)). You can assume the result of g(x) is a valid input for f
    and vice versa.

    >>> add_one = lambda x: x + 1        # adds one to x
    >>> square = lambda x: x**2          # squares x [returns x^2]
    >>> b1 = composite_identity(square, add_one)
    >>> b1(0)                            # (0 + 1) ** 2 == 0 ** 2 + 1
    True
    >>> b1(4)                            # (4 + 1) ** 2 != 4 ** 2 + 1
    False
    """
    "*** YOUR CODE HERE ***"
    return lambda x: f(g(x)) == g(f(x))

